Electroactive polymer transducers for sensory feedback applications

ABSTRACT

Electroactive polymer transducers for sensory feedback applications are disclosed.

FIELD OF THE INVENTION

The present invention is directed to the use of electroactive polymertransducers to provide sensory feedback.

BACKGROUND

There are many known user interface devices which employ hapticfeedback—the communication of information to a user through forcesapplied to the user's body, typically in response to a force initiatedby the user. Examples of user interface devices which may employ hapticfeedback include keyboards, touch screens, computer mice, trackballs,stylus sticks, joysticks, etc. The haptic feedback provided by thesetypes of interface devices is in the form of physical sensations, suchas vibrations, pulses, spring forces, etc., which are felt by the user.

Often, a user interface device with haptic feedback can be an inputdevice which “receives” an action initiated by the user as well as anoutput device which provides haptic feedback indicating that the actionwas initiated. In practice, the position of some contacted or touchedportion or surface, e.g., a button, of a user interface device ischanged along at least one degree of freedom by the force applied by theuser, where the force applied must reach some minimum threshold value inorder for the contacted portion to change positions and to effect thehaptic feedback. Achievement or registration of the change in positionof the contacted portion results in a responsive force (e.g.,spring-back, vibration, pulsing) which is also imposed on the contactedportion of the device acted upon by the user, which force iscommunicated to the user through his or her sense of touch.

One common example of a user interface device that employs a spring-backor “bi-phase” type of haptic feedback is a button on a mouse. The buttondoes not move until the applied force reaches a certain threshold, atwhich point the button moves downward with relative ease and thenstops—the collective sensation of which is defined as “clicking” thebutton. The user-applied force is substantially along an axisperpendicular to the button surface, as is the responsive (but opposite)force felt by the user.

Haptic feedback capabilities are known to improve user productivity andefficiency, particularly in the context of data entry. It is believed bythe inventors hereof that further improvements to the character andquality of the haptic sensation communicated to a user may furtherincrease such productivity and efficiency. It would be additionallybeneficial if such improvements were provided by a sensory feedbackmechanism which is easy and cost-effective to manufacture, and does notadd to, and preferably reduces, the space, size and/or mass requirementsof known haptic feedback devices.

SUMMARY OF THE INVENTION

The present invention includes devices, systems and methods involvingelectroactive transducers for sensory applications. In one variation, auser interface device having sensory feedback is provided. The deviceincludes a user contact surface, an electroactive polymer transducercomprising an output member coupled to the contact surface, a sensor forsensing a mechanical force on the user contact surface and providing anactivation signal to the transducer, wherein activation of thetransducer moves at least a portion the user contact surface.

The coupling between the output member of the transducer and the usercontact surface may include a mechanical means, magnetic means or both.In certain variations in which a mechanical coupling means is employed,at least one pin or protrusion extending between the output member andthe user contact surface is provided. Where the pin or pins extendsthrough the transducer sealing material, a compliant material may beused between the pin and the sealing material to ensure that the seal isnot compromised upon movement of the pins. In certain embodiments, apivotable lever is used to transfer motion from the transducer outputmember to the user contact surface whereby the pins extend from thelever through countersunk holes provided within the sealing material.

The user interface device may further include a sealing material adaptedto substantially hermetically seal the transducer. A13. In certainembodiments, the sealing material forms a gasket between the usercontact surface and the transducer, while in others, the sealingmaterial encases the transducer.

The user interface device may be configured to provide a sensoryfeedback movement, i.e., movement of the contact surface which is sensedby the user, which is in a lateral or in a vertical direction relativeto the contact surface. The user interface device may provide a singleinput or contact surface, e.g., a keypad, or may be provided in an arrayformat having a plurality of contact surfaces, e.g., a keyboard.

The devices and systems of the present invention may be fabricated atleast in part by web-based manufacturing techniques. For example, onesuch method includes forming at lest the transducers by such techniqueswhere an electroactive polymer film is provided and an array ofelectrodes is formed on the film. The electrode array is then sandwichedbetween a top and bottom array of frame components to form an array ofelectroactive polymer transducers. The resulting array may be kept inarray format or may be singulated into a plurality of individualtransducers, depending on the type of user interface device.

These and other features, objects and advantages of the invention willbecome apparent to those persons skilled in the art upon reading thedetails of the invention as more fully described below.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is best understood from the following detailed descriptionwhen read in conjunction with the accompanying schematic drawings. Tofacilitate understanding, the same reference numerals have been used(where practical) to designate similar elements that are common to thedrawings. Included in the drawings are the following:

FIGS. 1A-1C show top perspective, bottom perspective and cross-sectionalviews, respectively, of a sensory feedback device of the presentinvention;

FIGS. 2A and 2B show exploded top and bottom perspective views,respectively, of the sensory feedback device of FIGS. 1A-1C;

FIG. 3A is a top planar view of an assembled electroactive polymeractuator of the present invention; FIGS. 3B and 3C are top and bottomplanar views, respectively, of the film portion of the actuator of FIG.3A and, in particular, illustrate the two-phase configuration of theactuator;

FIG. 4 illustrates a side view of the sensory feedback device of FIGS.1A-1C with a human finger in operative contact with the contact surfaceof the device;

FIGS. 5A and 5B graphically illustrate the force-stroke relationship andvoltage response curves, respectively, of the actuator of FIGS. 3A-3Cwhen operated in a single-phase mode;

FIGS. 6A and 6B graphically illustrate the force-stroke relationship andvoltage response curves, respectively, of the actuator of FIGS. 3A-3Cwhen operated in a two-phase mode;

FIG. 7 is a block diagram of electronic circuitry, including a powersupply and control electronics, for operating the sensory feedbackdevice of FIGS. 1A-1C;

FIG. 8 illustrates an alternate bi-stable embodiment of a sensoryfeedback device of the present invention;

FIGS. 9A and 9B show exploded top and bottom perspective views,respectively, of another tactile feedback device of the presentinvention in which magnets are used to couple the actuator to thecontact surface of the device;

FIGS. 10A and 10B illustrate perspective assembled and exploded views,respectively, of a hermetically sealed electroactive polymer actuator ofthe present invention for use in the tactile feedback devices of thepresent invention;

FIGS. 11A and 11B illustrate perspective assembled and exploded views,respectively, of another hermetically sealed electroactive polymeractuator of the present invention for use in the tactile feedbackdevices of the present invention;

FIGS. 12A-12C illustrate assembled, exploded and cross-sectional views,respectively, of another hermetically sealed electroactive polymeractuator of the present invention for use in the tactile feedbackdevices of the present invention;

FIGS. 13A-13C illustrate another haptic feedback device of the presentinvention employing another variation of a hermetically sealed actuator;

FIGS. 14A and 14B illustrate arrays, respectively, of electrode patternsdisposed on opposite sides of a dielectric film material for use in anarray of haptic feedback devices of the present invention;

FIG. 15 is an exploded view of an array of actuators for use in thesensory feedback devices of the present invention;

FIG. 16 is an assembled view of an array of actuators of the typeillustrated in FIGS. 3A-3C; and

FIG. 17 is an assembled view of an array of actuators of the typeillustrated in FIG. 8.

Variation of the invention from that shown in the figures iscontemplated.

DETAILED DESCRIPTION OF THE INVENTION

The devices, systems and methods of the present invention are nowdescribed in detail with reference to the accompanying figures.

Referring to FIGS. 1A-1C, 2A and 2B, various views of are provided of anembodiment of a sensory feedback device 2 of the present invention whichmay be employed within a user interface device (not shown), such as witha single key within a keyboard or a discrete area of a touch screen. Inan assembled form, as shown in FIGS. 1A-1C, sensory feedback device 2has a very thin, low profile configuration (best illustrated in FIG. 1C)which may have any suitable width, length and height (thickness)dimensions to accommodate the user interface device component with whichit is to be used. Typically, the width and length dimensions of device 2substantially match or are within the width and length dimensions of theuser contact surface with which it is associated. For example, forfinger key or touch applications, the width and length dimensions ofdevice 2 are typically in the range from about 10 mm to about 30 mm forsquare keys. The height or thickness dimension of device 2 is preferablyas small as practically possible so as to reduce the profile (and size,weight and mass) of the device. For keypad applications, the thicknessdimension of the device is typically about 2 mm, but may be less thanabout 1 mm.

Sensory or haptic feedback device 2 includes various componentsincluding, from top to bottom as illustrated in FIGS. 2A an 2B, a userinterface pad 4 having a top contact surface 4 a and a bottom surface 4b having a plurality of protrusions 16, the function of which isdiscussed below. Top surface 4 a may optionally be textured to minimizeslippage by a user's finger. Pad 4 is positioned atop a sensory feedbackmechanism or actuator 30. Actuator 30 includes an electroactive polymer(EAP) transducer 10 in the form of an elastic film which convertselectrical energy to mechanical energy. The resulting mechanical energyis in the form of physical “displacement” of an output member, here inthe form of a disc 28 (discussed in greater detail below), whichdisplacement is sensed or felt by the user's finger.

With reference to FIGS. 3A-3C, EAP transducer film 10 comprises twoworking pairs of thin elastic electrodes 32 a, 32 b and 34 a, 34 b whereeach working pair is separated by a thin layer of elastomeric dielectricpolymer 26 (e.g., made of acrylic, silicone, or the like). When avoltage difference is applied across the oppositely-charged electrodesof each working pair (i.e., across electrodes 32 a and 32 b, and acrosselectrodes 34 a and 34 b), the opposed electrodes attract each otherthereby compressing the dielectric polymer layer 26 therebetween. As theelectrodes are pulled closer together, the dielectric polymer 26 becomesthinner (i.e., the z-axis component contracts) as it expands in theplanar directions (i.e., the x- and y-axes components expand) (see FIGS.3B and 3C for axis references). Furthermore, like charges distributedacross each electrode cause the conductive particles embedded withinthat electrode to repel one another, thereby contributing to theexpansion of the elastic electrodes and dielectric films. The dielectriclayer 26 is thereby caused to deflect with a change in electric field.As the electrode material is also compliant, the electrode layers changeshape along with dielectric layer 26. Generally speaking, deflectionrefers to any displacement, expansion, contraction, torsion, linear orarea strain, or any other deformation of a portion of dielectric layer26. This deflection may be used to produce mechanical work.

In fabricating transducer 20, elastic film is stretched and held in apre-strained condition by two opposing rigid frame sides 8 a, 8 b. Ithas been observed that the pre-strain improves the dielectric strengthof the polymer layer 26, thereby improving conversion between electricaland mechanical energy, i.e., the pre-strain allows the film to deflectmore and provide greater mechanical work. Typically, the electrodematerial is applied after pre-straining the polymer layer, but may beapplied beforehand. The two electrodes provided on the same side oflayer 26, referred to herein as same-side electrode pairs, i.e.,electrodes 32 a and 34 a on top side 26 a of dielectric layer 26 (seeFIG. 3B) and electrodes 32 b and 34 b on bottom side 26 b of dielectriclayer 26 (see FIG. 3C), are electrically isolated from each other byinactive areas or gaps 25. The opposed electrodes on the opposite sidesof the polymer layer from two sets of working electrode pairs, i.e.,electrodes 32 a and 32 b for one working electrode pair and electrodes34 a and 34 b for another working electrode pair. Each same-sideelectrode pair preferably has the same polarity, while the polarity ofthe electrodes of each working electrode pair are opposite each other,i.e., electrodes 32 a and 32 b are oppositely charged and electrodes 34a and 34 b are oppositely charged. Each electrode has an electricalcontact portion 35 configured for electrical connection to a voltagesource (not shown).

In the illustrated embodiment, each of the electrodes has asemi-circular configuration where the same-side electrode pairs define asubstantially circular pattern for accommodating a centrally disposed,rigid output disc 20 a, 20 b on each side of dielectric layer 26. Discs20 a, 20 b, the functions of which are discussed below, are secured tothe centrally exposed outer surfaces 26 a, 26 b of polymer layer 26,thereby sandwiching layer 26 therebetween. The coupling between thediscs and film may be mechanical or be provided by an adhesive bond.Generally, the discs 20 a, 20 b will be sized relative to the transducerframe 22 a, 22 b. More specifically, the ratio of the disc diameter tothe inner annular diameter of the frame will be such so as to adequatelydistribute stress applied to transducer film 10. The greater the ratioof the disc diameter to the frame diameter, the greater the force of thefeedback signal or movement but with a lower linear displacement of thedisc. Alternately, the lower the ratio, the lower the output force andthe greater the linear displacement.

Because of their light weight and minimal components, EAP transducersoffer a very low profile and, as such, are ideal for use insensory/haptic feedback applications. Examples of EAP transducers andtheir construction are described in U.S. Pat. Nos. 7,368,862; 7,362,031;7,320,457; 7,259,503; 7,233,097; 7,224,106; 7,211,937; 7,199,501;7,166,953; 7,064,472; 7,062,055; 7,052,594; 7,049,732; 7,034,432;6,940,221; 6,911,764; 6,891,317; 6,882,086; 6,876,135; 6,812,624;6,809,462; 6,806,621; 6,781,284; 6,768,246; 6,707,236; 6,664,718;6,628,040; 6,586,859; 6,583,533; 6,545,384; 6,543,110; 6,376,971 and6,343,129; and U.S. Published Patent Application Nos. 2006/0208610;2008/0022517; 2007/0222344; 2007/0200468; 2007/0200467; 2007/0200466;2007/0200457; 2007/0200454; 2007/0200453; 2007/0170822; 2006/0238079;2006/0208610; 2006/0208609; and 2005/0157893, the entireties of whichare incorporated herein by reference.

Referring again to FIGS. 2A and 2B, a backstop or insulator shield 6 amade of an insulating and preferably shock-absorbing material isprovided between contact pad 4 and the top surface of top transducerframe 8 a. Insulating shield 6 a also acts a slide bearing surface forcontact pad 4. To mechanically couple contact pad 4 with transducer 30,cut-outs or thru-holes 18 are provided within backstop 6 a andthru-holes 28 are provided within discs 20 a and 20 b as well as withindielectric film 26 to receive and accommodate protrusions or pins 16extending from the underside 4 b of contact pad 4. The thru-holes 28within the transducer component layers may also serve to receive a means(not shown), e.g., bolts, threaded bosses, for mechanically coupling thelayers together. Optionally, a bottom backstop or shield 6 b may beprovided on the bottom side of transducer frame 8 b to providemechanical stability as well as to act as an additional shock absorber.

The bottom side of sensory feedback device 2 includes a plate 12 whichprovides mechanical stability to device 2 by way of a mechanicalcoupling (not shown), e.g., bolts, which are placed in thru-holes 24within each of the above described layers of device 2. Plate 12 alsofunctions as an electrical adaptor having electrical traces or contacts14 a, 14 b, 14 c, which may be in the form a printed circuit boardhoused within the user interface device, for electrical communicationwith the control electronics and a source of power (discussed in greaterdetail below). The exemplary pattern of electrical traces includestraces 14 a and 14 b for connection to each of the two designate highvoltage electrodes and a single trace 14 c for connection to both of thegrounded electrodes.

With its overall very low-profile and square shape, the sensory/hapticfeedback devices of the present invention are particularly suitable foruse in a keyboard, touch screen, computer mouse and other user interfacedevices where only a single finger 38 is used to contact the inputportion of the device, as illustrated in FIG. 4. However, those skilledin the art will appreciate other configurations that are suitable foruser interface devices designed for contact by a user's palm or with ahand grip, such as trackballs, stylus sticks, joysticks, etc.

With the electrode configuration described above (i.e., two workingelectrode pairs), transducer 10 is capable of functioning in either asingle or a two-phase mode. In the manner configured, the mechanicaldisplacement of the output component, i.e., the two coupled discs 20 aand 20 b, of the subject sensory feedback device described above has islateral rather than vertical. In other words, instead of the sensoryfeedback signal being a force in a direction perpendicular to thecontact surface 4 a of the user interface pad 4 and parallel to theinput force (designated by arrow 60 a in FIG. 4) applied by the user'sfinger 38 (but in the opposing or upward direction), the sensed feedbackor output force (designated by double-head arrow 60 b in FIG. 4) of thesensory/haptic feedback devices of the present invention is in adirection parallel to the contact surface 4 a and perpendicular to inputforce 60 a. Depending on the rotational alignment of the electrode pairsabout an axis perpendicular to the plane of transducer 10 and relativeto the position of the user interface pad 4, e.g., a keyboard key pad,and the mode in which the transducer is operated (i.e., single phase ortwo phase), this lateral movement may be in any direction or directionswithin 360°. For example, the lateral feedback motion may be from sideto side or up and down (both are two-phase actuations) relative to theforward direction of the user's finger (or palm or grip, etc.). Whilethose skilled in the art will recognize certain other actuatorconfigurations which provide a feedback displacement which is transverseor perpendicular to the contact surface of the haptic feedback device,the overall profile of a device so configured may be greater than theaforementioned design.

When operating sensory/haptic feedback device 2 in single-phase mode,only one working pair of electrodes of actuator 30 would be activated atany one time. The single-phase operation of actuator 30 may becontrolled using a single high voltage power supply. As the voltageapplied to the single-selected working electrode pair is increased, theactivated portion (one half) of the transducer film will expand, therebymoving the output disc 20 in-plane in the direction of the inactiveportion of the transducer film. FIG. 5A illustrates the force-strokerelationship of the sensory feedback signal (i.e., output discdisplacement) of actuator 30 relative to neutral position whenalternatingly activating the two working electrode pairs in single-phasemode. As illustrated, the respective forces and displacements of theoutput disc are equal to each other but in opposite directions. FIG. 5Billustrates the resulting non-linear relationship of the applied voltageto the output displacement of the actuator when operated in thissingle-phase mode. The “mechanical” coupling of the two electrode pairsby way of the shared dielectric film may be such as to move the outputdisc in opposite directions. Thus, when both electrode pairs areoperated, albeit independently of each other, application of a voltageto the first working electrode pair (phase 1) will move the output disc20 in one direction, and application of a voltage to the second workingelectrode pair (phase 2) will move the output disc 20 in the oppositedirection. As the various plots of FIG. 5B reflect, as the voltage isvaried linearly, the displacement of the actuator is non-linear.

To effect a greater displacement of the output member or component, andthus provide a greater sensory feedback signal to the user, actuator 30is operated in a two-phase mode, i.e., activating both portions of theactuator simultaneously. FIG. 6A illustrates the force-strokerelationship of the sensory feedback signal of the output disc when theactuator is operated in two-phase mode. As illustrated, both the forceand stroke of the two portions 32, 34 of the actuator in this mode arein the same direction and have double the magnitude than the force andstroke of the actuator when operated in single-phase mode. FIG. 6Billustrates the resulting linear relationship of the applied voltage tothe output displacement of the actuator when operated in this two-phasemode. By connecting the mechanically coupled portions 32, 34 of theactuator electrically in series and controlling their common node 55,such as in the manner illustrated in the block diagraph 40 of FIG. 7,the relationship between the voltage of the common node 55 and thedisplacement (or blocked force) of the output member (in whateverconfiguration) approach a linear correlation. In this mode of operation,the non-linear voltage responses of the two portions 32, 34 of actuator30 effectively cancel each other out to produce a linear voltageresponse. With the use of control circuitry 44 and switching assemblies46 a, 46 b, one for each portion of the actuator, this linearrelationship allows the performance of the actuator to be fine-tuned andmodulated by the use of varying types of waveforms supplied to theswitch assemblies by the control circuitry. Another advantage of usingcircuit 40 is ability to reduce the number of switching circuits andpower supplies needed to operate the sensory feedback device. Withoutthe use of circuit 40, two independent power supplies and four switchingassemblies would be required. Thus, the complexity and cost of thecircuitry are reduced while the relationship between the control voltageand the actuator displacement are improved, i.e., made more linear.

Various types of mechanisms may be employed to communicate the inputforce 60 a from the user to effect the desired sensory feedback 60 b(see FIG. 4). For example, a capacitive or resistive sensor 50 (see FIG.7) may be housed within the user interface pad 4 to sense the mechanicalforce exerted on the user contact surface input by the user. Theelectrical output 52 from sensor 50 is supplied to the control circuitry44 which in turn triggers the switch assemblies 46 a, 46 b to apply thevoltage from power supply 42 to the respective transducer portions 32,34 of the sensory feedback device in accordance with the mode andwaveform provided by the control circuitry.

Referring now to FIG. 8, there is illustrated another actuatorembodiment 70 of the present invention for use in a sensory/hapticfeedback device of the present invention. Actuator 70 includes the samebasic actuator structure 30 described above with the inclusion of amechanism 72 which imposes a negative spring rate bias on output disc20. Negative spring rate mechanism 72 includes a central hub 76mechanically coupled to output disc 20 and two opposing leaf springflexures 74 a and 74 b extending between hub 76 and a frame side 8 a ofthe actuator. The flexures 74 a, 74 b are each coupled to the hub andframe by living spring joints 78. Whether operated in single-phase ortwo-phase mode, the actuator is inherently bi-stable. An advantage ofnegative biasing, at least in the context of the subject actuators, isthat as the displacement/stroke distance of the output elementincreases, significantly less force is need to achieve a greater strokedistance. The force-stoke relationship of negative force biasing isdescribed in detail in U.S. patent application Ser. No. 11/618,577,which is herein incorporated by reference in its entirety.

Another variation of the present invention involves the hermetic sealingof the EAP actuators to minimize any effects of humidity or moisturecondensation that may occur on the EAP film. For the various embodimentsdescribed below, the EAP actuator is sealed in a barrier filmsubstantially separately from the other components of the tactilefeedback device. The barrier film or casing may be made of, such asfoil, which is preferably heat sealed or the like to minimize theleakage of moisture to within the sealed film. Each of these deviceembodiments enables coupling of the feedback motion of the actuator'soutput member to the contact surface of the user input surface, e.g.,keypad, while minimizing any compromise in the hermetically sealedactuator package. Various exemplary means for coupling the motion of theactuator to the user interface contact surface are also provided.

One such coupling means involves the use of magnets. FIGS. 9A and 9Billustrate a tactile feedback device employing such magnetic coupling.Device 80 includes user interface key cap 82 and EAP actuator 86, wherethe actuator is optionally hermetically sealed by top and bottom covers88 and 90 which are made of magnetically inert, rigid materials. The keycap and actuator components are coupled by means of opposing magneticunits. A first magnetic unit 96 a/b is provided centrally suspendedwithin EAP film 84 held by frame 92. This magnetic unit, in essence,acts as the output member of actuator 86 and is displaced laterally orin-plane, as discussed above, upon actuation of the actuator. The secondmagnetic unit 102 a/b is held by another cartridge 84, similarlyconstructed and sized to the actuator cartridge 86 in that a film 100 isheld stretched within an open frame 98 with the magnetic unit heldcentrally suspended therein; however, unlike EAP film 84, film 100 ispassive, i.e., has no electrodes. Key pad 82 or at least its undersideis made of a material that is attractable to magnetic unit 102, therebyfixing the key pad to suspension cartridge 98. Both magnetic units aretypically disc-shaped and may comprise a single magnet or a pair ofstacked magnetic discs. In the latter arrangement, as illustrated in theFIGS. 9A and 9B, the two magnets of each pair (96 a, 96 b and 102 a, 102b) may be oppositely polarized and thereby fixed together. The opposingsuspension and actuator magnetic units may either be oppositelypolarized or similarly polarized. When oppositely polarized (i.e., N-S),the magnetic units 96, 102 attract each other (through top sealing layer88) and, thus, move in parallel/tandem upon actuation of actuator 92,i.e., the feedback motion of the keypad is in the same planar directionas that of the displacement output of the actuator. When the magneticunits 96, 102 have he same polarization (i.e., either N-N or S-S), theyrepel each other resulting in the units moving both vertically andhorizontally away from each other, i.e., the feedback motion of thekeypad is in the opposite direction as that of the displacement outputof the actuator. In the latter arrangement, the respective films 94, 100must have sufficient suspension to counter the displacement of themagnetic units caused by the repulsion. An advantage of the repellingarrangement over the attracting arrangement is that it reduces thefriction between the magnets and casing 88.

Another embodiment of a sealed actuator is illustrated in FIGS. 10A and10B. Actuator package 110 includes actuator cartridge 112 sealed betweena top and base barriers 114, 116. Actuator cartridge 112 includes openframe 122 having an EAP film 124 stretched between it and a centrallypositioned output disc 126. Two (or more) protrusions or pins 120 extendfrom atop output disc 126 and extend through corresponding holes 118within top sealing barrier 114 for mechanical coupling to a user inputkey (not shown). As such, movement of output disc 126, i.e., in theplanar direction as configured, in turn translates the user input key.Mounted circumferentially about pins 120 or within holes 118 is acompliant barrier film, such as styrene-ethylene-butadiene-styrene(SEBS) block copolymer, in the form of a ring to provide an elastic andflexible seal therebetween. As such, the pins provide a bridge betweenthe actuator and user interface pad that does not disrupt the hermeticseal about the actuator.

FIGS. 11A and 11B illustrate another sealed actuator package 130 havingan actuator cartridge 132 sealed between top and base barriers 134, 136.Actuator cartridge 132 has an open frame 140 and an EAP film 148stretched between it and a centrally positioned output disc 138. Topbarrier 134 has a central section 144 having a shape and diametersubstantially matching that of output disc 138. The gap or spacing 145between the central section 144 and the outer portion of barrier 134holds a compliant film material, SEBS block copolymer, to allow movementof the central portion without compromising the sealed actuator.Centrally disposed holes 142 and 146, respectively, within each of theactuator output member 138 and barrier film section 144 are aligned toprovide a thru hole for receiving a pin, screw or the like for couplingthe actuator output motion to a user input member (not shown).

FIGS. 12A-12C illustrate another sealed actuator 150 of the presentinvention. Actuator package 150 includes actuator cartridge 152 sealedbetween a top and base barriers 154, 156. Actuator cartridge 152includes open frame 160 having an EAP film 164 stretched between it anda centrally positioned output disc 162. Two diametrically opposing pinholes extend through top barrier 154 (166 a, 166 b) and output disc 162(162 a, 162 b) for receiving the legs 158 a of a lever bar 158. Theholes 166 a, 166 b are countersunk (best illustrated in FIG. 12C) toallow the pins 158 a to pivot therein. As such, when actuator 152 isactivated with the resulting planar translation of output disc 162, thepins are caused to pivot about the fulcrum defined by the countersunkholes 168 a, 168 b. The resulting movement of lever bar 158, illustratedby arrows 168 in FIG. 12C, is in a direction perpendicular to thealignment of the bar. The countersunk configuration of these holesallows a close fit between the lever legs and the holes within the topbarrier so as to form a seal. Optionally, the legs may be coated with acompliant material to provide a more hermetically sealed environment.

FIG. 13A illustrates another manner of hermetically sealing the actuatoremployed in a haptic feedback device 170 of the present invention. Theactuator includes open frame 174, output disc 176 and EAP film 178extending therebetween. The actuator is positioned atop a back plate 188and beneath a keypad 172. Extending about the perimeter of the keypad172 and between the keypad and actuator frame 174 is a vapor barriermembrane or gasket 184. Membrane may be molded from SEBS, Butyl, or thelike. The outer edge of the assembly, including barrier membrane 184, isencased by a sealed packaging 182, which may comprise top and bottomfoil layers 180, 182 or the like which are heat sealed together.Optionally, a desiccant or buffer 186 may be positioned within the spacebetween the keypad and the actuator. FIGS. 13B and 13C illustrate device170 (shown without the desiccant and foil packaging for clarity) whenthe actuator component is in passive and active states, respectively. Inthe passive state (FIG. 13B), like the actuator EAP film 178, thebarrier membrane 184 has a symmetrical configuration about key pad 172.In the active state (FIG. 13C), the EAP film is selectively activatedand/or configured such that output disc 176 moves laterally in onedirection, as indicated by arrow 190. In turn, keypad 172 is caused tomove in the same direction. The barrier film material 184 is able tostretch and compress to accommodate the movement of keypad 172.

The actuators of the present invention may be provided in a planar arrayfabricated by continuous web-based manufacturing techniques. Such arraysare highly practical as sensory/haptic feedback devices are oftenprovided in array formats themselves. A computer keyboard is a commonexample of such. FIGS. 14-17 illustrate arrays of various components ofthe haptic devices of the present invention at various points in the webfabrication process.

FIGS. 14A and 14B illustrate high voltage and ground sides 200 a and 200b, respectively, of an EAP film array 200 (see FIG. 15) for use in anarray of EAP actuators for use in the tactile feedback devices of thepresent invention. Film array 200 includes an electrode array providedin a matrix configuration to increase space and power efficiency. Thehigh voltage side 200 a of the EAP film array provides electrodepatterns 202 running in vertically (according to the view pointillustrated in FIG. 14A) on dielectric film 208 material. Each pattern202 includes a pair of high voltage lines 202 a, 202 b. The opposite orground side 200 b of the EAP film array provides electrode patterns 206running transversally relative to the high voltage electrodes, i.e.,horizontally. Each pattern 206 includes a pair of ground lines 206 a,206 b. Each pair of opposing high voltage and ground lines (202 a, 206 aand 202 b, 206 b) provides a separately activatable electrode pair suchthat activation of the opposing electrode pairs provides a two-phaseoutput motion in the directions illustrated by arrows 212. The assembledEAP film array 200 (illustrating the intersecting pattern of electrodeson top and bottom sides of dielectric film 208) is provided in FIG. 15within an exploded view of an array 204 of EAP transducers 222, thelatter of which is illustrated in its assembled form in FIG. 16. EAPfilm array 200 is sandwiched between opposing frame arrays 214 a, 214 b,with each individual frame segment 216 within each of the two arraysdefined by a centrally positioned output disc 218 within an open area.Each combination of frame/disc segments 216 and electrode configurationsform an EAP transducer 222. Depending on the application and type ofactuator desired, additional layers of components may be added totransducer array 204. For example, to form an array of the bi-stable EAPactuators of FIG. 8, an additional array layer 226 of negative springrate flexures 224 is provided on one side of the transducer array 204.The complete transducer layer 220 having an array of EAP transducers 228is illustrated in exploded and assembled views in FIGS. 15 and 17,respectively. The transducer array 220 may be incorporated in whole to auser interface array, such as a keyboard, for example, or the individualtransducers 228 may be singulated for use in individual user interfacedevices, such as individual keypads, for example.

Regarding methodology, the subject methods may include each of themechanical and/or activities associated with use of the devicesdescribed. As such, methodology implicit to the use of the devicesdescribed forms part of the invention. Other methods may focus onfabrication of such devices.

As for other details of the present invention, materials and alternaterelated configurations may be employed as within the level of those withskill in the relevant art. The same may hold true with respect tomethod-based aspects of the invention in terms of additional acts ascommonly or logically employed. In addition, though the invention hasbeen described in reference to several examples, optionallyincorporating various features, the invention is not to be limited tothat which is described or indicated as contemplated with respect toeach variation of the invention. Various changes may be made to theinvention described and equivalents (whether recited herein or notincluded for the sake of some brevity) may be substituted withoutdeparting from the true spirit and scope of the invention. Any number ofthe individual parts or subassemblies shown may be integrated in theirdesign. Such changes or others may be undertaken or guided by theprinciples of design for assembly.

Also, it is contemplated that any optional feature of the inventivevariations described may be set forth and claimed independently, or incombination with any one or more of the features described herein.Reference to a singular item, includes the possibility that there areplural of the same items present. More specifically, as used herein andin the appended claims, the singular forms “a,” “an,” “said,” and “the”include plural referents unless the specifically stated otherwise. Inother words, use of the articles allow for “at least one” of the subjectitem in the description above as well as the claims below. It is furthernoted that the claims may be drafted to exclude any optional element. Assuch, this statement is intended to serve as antecedent basis for use ofsuch exclusive terminology as “solely,” “only” and the like inconnection with the recitation of claim elements, or use of a “negative”limitation. Without the use of such exclusive terminology, the term“comprising” in the claims shall allow for the inclusion of anyadditional element—irrespective of whether a given number of elementsare enumerated in the claim, or the addition of a feature could beregarded as transforming the nature of an element set forth n theclaims. Stated otherwise, unless specifically defined herein, alltechnical and scientific terms used herein are to be given as broad acommonly understood meaning as possible while maintaining claimvalidity.

In all, the breadth of the present invention is not to be limited by theexamples provided.

1. A user interface device having sensory feedback comprising: a usercontact surface; an electroactive polymer transducer comprising anoutput member coupled to the contact surface; a sensor for sensing amechanical force on the user contact surface and providing an activationsignal to the transducer, at least one pin extending between the outputmember and the user contact surface; a compliant material between thepin and the sealing material; and a scaling material adapted tosubstantially hermetically seal the transducer, wherein activation ofthe transducer moves at least a portion of the user contact surface,wherein the output member is mechanically coupled to the user contactsurface, and wherein the at least one pin extends through the sealingmaterial.
 2. The user interface device of claim 1, wherein the movementof the contact surface is in a lateral direction.
 3. The user interfacedevice of claim 1, wherein the user contact surface comprises a keypad.4. The user interface device of claim 1, wherein the sealing materialcomprises a countersunk hole for receiving a pin.
 5. The user interfacedevice of claim 4, wherein the at least one pin extends from a pivotablelever.
 6. The user interface device of claim 1, wherein the outputmember is magnetically coupled to the user contact surface.
 7. The userinterface device of claim 1, wherein the transducer comprises anelectroactive polymer film extending between the output member and anopen frame.
 8. The user interface device of claim 1, wherein thetransducer further comprises a negative spring rate bias mechanismassociated with the output member.
 9. The user interface device of claim1, wherein the sealing material forms a gasket between the user contactsurface and the transducer.
 10. The user interface device of claim 1,wherein the sealing material encases the transducer.
 11. The userinterface device of claim 1, wherein the transducer is activatable intwo phases.
 12. The user interface device of claim 1, wherein thetransducer is formed at least in part by web-based manufacturingtechniques.
 13. A user interface device having sensory feedbackcomprising: a user contact surface; an electroactivc polymer transducercomprising an output member coupled to the contact surface; and a motioncoupling mechanism extending between the user contact surface and thetransducer, wherein activation of the transducer moves at least aportion of the user contact surface and wherein the motion couplingmechanism is magnetic.